Your search keyword '"precast structures"' showing total 184 results

1. Study of Different Modeling Approaches of Precast Structural Wall Systems for Seismic Analysis

Author

Chougule, Shashiraj Shivling, Bharti, S. D., Shrimali, M. K., Ingle, Anand Surendra, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Goel, Manmohan Dass, editor, Biswas, Rahul, editor, and Dhanvijay, Sonal, editor

Published

2025

2. Seismic Retrofitting of Reinforced Concrete Buildings with Rotational Friction Dampers

Author

Mualla, I., Yildrim, S., Tonguc, Y., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Sigaher, Ani Natali, editor, Sutcu, Fatih, editor, and Yenidogan, Cem, editor

Published

2024

3. Earthquake Sequence in Kahramanmaraş, Turkey – Report on the Behaviour of Precast Industrial Buildings and Proposals for Improvement

Author

Thanopoulos, Pavlos, Bampatsikos, Minoas-Vasileios, Vayas, Ioannis, Dinu, Florea, Neagu, Calin, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Mazzolani, Federico M., editor, Piluso, Vincenzo, editor, Nastri, Elide, editor, and Formisano, Antonio, editor

Published

2024

4. Dynamical analysis of a 40 m span precast posttensioned concrete girder during lifting operations.

Author

de Lima, Gabriel Henrique Arruda Tavares, Krahl, Pablo Augusto, Siqueira, Tiago Morkis, and de Lima, Maria Cristina Vidigal

Subjects

*CONCRETE beams, *GIRDERS, *MODAL analysis, *PRECAST concrete, *PRESTRESSED concrete, *FINITE element method, *CRITICAL velocity

Abstract

Cranes are employed to lift precast concrete girders during their construction. Presently, there is no recommendation for operational velocities during girder assemblage, particularly for long elements; simultaneously, several accidents have been reported during the transitory phase of girder motion. Since this mechanical problem has been examined in technical literature using a static approach, the present research study aims to investigate the dynamical behavior of a long, prestressed concrete girder by determining critical operational velocities according to crane movements. Prestressing cables' eccentricity and lifting loop position deviation were accounted for in 3D finite element simulations of a 40 m span precast prestressed concrete girder. Transient nonlinear analyses to obtain stresses and deflections were performed, so as to account for the large deformation behavior of the motion. A frequency domain approach was employed to analyze the time history results using the girder's natural frequencies obtained by modal analysis. The finite element model was developed to simulate upward, downward, and lateral girder movements. The most significant displacements and stresses were observed in the highest girder acceleration peaks, amplified by eccentricities. Safety against cracking and subsequent failure during vertical and lateral movements was ensured for crane operating accelerations of 0.02 g (v = 20 cm/s) and 0.007 g (v = 7 cm/s), respectively. Compared with the usual static analysis, for the critical case investigated, the inertial effect intensified the tensile stresses by 27 times, increased the compressive stresses by 11%, and increased the girder deflection by 3 times. [ABSTRACT FROM AUTHOR]

Published

2024

5. Upgrading of Precast Roof Beam–Column Connections with Seismic Safety Key Devices.

Author

Ristic, Jelena, Misini, Labeat, Ristic, Danilo, and Hristovski, Viktor

Subjects

THREE-dimensional modeling, RETROFITTING, ENGINEERING, SAFETY

Abstract

To meet the increasing demands for innovations in precast systems with high seismic resistance, in this study, we introduced a novel seismic upgrading technique for roof beam-column (RBC) connections, termed the targeted seismic upgrading (TSU) method, incorporating the innovative seismic safety key (SSK) devices we developed. These devices significantly enhance seismic resilience, offering a substantial improvement over traditional pin-based RBC connections in precast structures, which are known to have limited effectiveness. Our experimental tests on half-scale models of conventional RBC connections, coupled with comprehensive refined finite element method-based nonlinear analytical studies, conclusively demonstrated the enhanced seismic retrofitting capabilities of RBC connections augmented with SSK devices. The paper delineates a technical procedure for applying the SSK, our proprietary innovation, for the targeted seismic upgrading of RBC connections within modern precast systems. Notably, the SSK-upgraded RBC connections exhibited a marked increase in safety, as evidenced by results from experimentally validated nonlinear three-dimensional micro-analytical models. The incorporated flexible design elements in the TSU method ensure its high effectiveness and general applicability for seismic upgrading of both existing and new precast industrial hall structures, offering a significant advancement in this specific seismic engineering topic [ABSTRACT FROM AUTHOR]

Published

2024

6. Seismic Risk and Finite Element Modelling Influence of an Existing One-Storey Precast Industrial Building.

Author

Bosio, Marco, Labò, Simone, Riva, Paolo, and Belleri, Andrea

Subjects

*FINITE element method, *ARCHITECTURAL details, *INDUSTRIAL buildings

Abstract

Precast structures are widely used in Southern Europe particularly for industrial buildings. Most of such buildings have been built before the enforcement of modern anti-seismic regulations showing a poor performance during past major earthquakes. Focusing on existing one-storey precast industrial buildings, the paper investigates the influence of modelling choices on the risk assessment, direct losses, and required structure retrofit time. RC forks, cladding panels, and elements connections were specifically considered. A precast industrial building with structural details compatible with 1980s Italian regulations was selected and analysed. In general, the failure was associated with the collapse of roof elements. [ABSTRACT FROM AUTHOR]

Published

2023

7. Hysteretic Performance of Precast Beam-Column Joint with Improved Energy Dissipation Capacity

Author

Gaur, Hitesh, Moka, Vijay Tarun Kumar, Rajendran, Siva Chidambaram, Kwatra, Naveen, Correia, José A. F. O., Series Editor, De Jesus, Abílio M. P., Series Editor, Ayatollahi, Majid Reza, Advisory Editor, Berto, Filippo, Advisory Editor, Fernández-Canteli, Alfonso, Advisory Editor, Hebdon, Matthew, Advisory Editor, Kotousov, Andrei, Advisory Editor, Lesiuk, Grzegorz, Advisory Editor, Murakami, Yukitaka, Advisory Editor, Carvalho, Hermes, Advisory Editor, Zhu, Shun-Peng, Advisory Editor, Bordas, Stéphane, Advisory Editor, Fantuzzi, Nicholas, Advisory Editor, Susmel, Luca, Advisory Editor, Dutta, Subhrajit, Advisory Editor, Maruschak, Pavlo, Advisory Editor, Fedorova, Elena, Advisory Editor, Fonseca de Oliveira Correia, José António, editor, and Choudhury, Satyabrata, editor

Published

2022

8. Experimental Investigation of Seismic Performance of Precast Concrete Wall–Beam–Slab Joints with Overlapping U-Bar Loop Connections.

Author

Chen, Feng, Yu, Zhiwu, Yu, Yalin, Zhai, Zhipeng, Liu, Qun, and Li, Xiao

Subjects

*CONCRETE joints, *PRECAST concrete, *PERSONAL computer performance, *ENERGY dissipation, *SHEAR walls, *CYCLIC loads, *STEEL walls

Abstract

In the era of energy conservation and environmental protection, as well as the industrialization of buildings, precast concrete (PC) structures have been developed and increasingly applied in construction industries due to their advantages of outstanding workability and ecofriendliness. In order to verify the reliability of overlapping U-bar loop connections and a modified form of these connections, and study the seismic performance of PC wall–beam–slab joints with these connection methods, three full-scale wall–beam–slab joints were designed and tested under low reversed cyclic loading, including one cast-in-place (CIP) specimen and two PC specimens. Based on the test results, the seismic performance of the PC joints was studied by comparing their damage process, hysteretic loops and skeleton curves, load-carrying capacity, ductility, equivalent stiffness, and energy dissipation with those of the CIP joint. After analyzing the experimental results, the following conclusions can be drawn: the overlapping U-bar loop connection and its modified form are effective and reasonable; the specimen with the modified connection form showed slightly better mechanical properties; the failure mode of the PC joints was consistent with that of the CIP joint; and the generation, distribution, and development of cracks in the PC specimens were similar to those in the CIP specimen. In addition, the stiffness of the PC joints was similar to that of the CIP joint, and the load-carrying capacity, ductility, and energy dissipation of the PC joints were better than those of the CIP joint. Moreover, the research in this paper can also provide some guidance for assembling wall–beam–slab joints in PC shear wall structures. [ABSTRACT FROM AUTHOR]

Published

2023

9. A Numerical Study on the Seismic Performance of a Horizontal Dry Connection for Precast Concrete Shear Walls.

Author

Sookree, Emmanuel Wayne, Huang, Zhuye, and Wang, Zhenyu

Abstract

Dry connections primarily consist of high-strength bolts and steel plates. They are commonly used in precast structures as they maximise time efficiency in the assembly stage compared with conventional methods. In this study, an embedded horizontal dry connection was developed using a square-shaped ring connector, high-strength hex nuts and flat washers, and grout for assembling precast concrete shear walls. Using Abaqus CAE 6.14, a numerical study was conducted on two full-scale RC shear walls including one monolithic and one precast specimen to assess the seismic performance of the bolted connection under the combined effect of axial and fully reversed cyclic loading. The average displacement ductility ratio of the precast specimen integrating the bolted connection was three times as much as the reference specimen. However, its relative energy dissipation capacity and shear strength were 21.94% and 27.92% lower, respectively. A parametric study was also carried out on the thickness and grade of the ring connector, grade of the vertical steel bars, number of ring connectors, and diameter of the vertical steel bars at the connection joints. Results showed that the seismic performance of the bolted connection was highly dependent on the bar diameter and number of ring connectors. [ABSTRACT FROM AUTHOR]

Published

2023

10. Tensile and flexural tests on ultrahigh performance concrete grouted sleeve connection.

Author

Qiu, Minghong, Shao, Xudong, Zhu, Yanping, Hussein, Husam H., and Liu, Yeping

Subjects

*TENSILE tests, *GROUTING, *FAILURE mode & effects analysis, *REINFORCING bars, *CONCRETE

Abstract

Connections in the assembled precast elements become essential locations for creating structural continuity. However, the construction challenges of conventional steel sleeve connections, such as rebar embedment length, rebar congestion, and formed grout defects (i.e., voids), are still a concern area for researchers and engineers. In this study, a proposed ultrahigh performance concrete (UHPC) grouted sleeve connection was presented for assembled precast elements, which might reduce defects, enhance durability, and accelerate structure construction. The tensile test of grouted sleeve connection with different grouting materials, rebar diameters, and anchoring lengths was conducted to determine an optimal anchoring length used in the flexural design. The precast specimens with the UHPC grouted sleeve connection were tested under flexural load. Also, strain changes in concrete, sleeve, and rebar were reported in tensile and flexural tests. The tensile test results showed two types of failure modes, the rebar rupture and bond failure between rebar and grouting. The recommended rebar anchoring length in the flexural design was six times the rebar diameter. The flexural test results showed that the precast specimen with or without the shear key has a similar failure mode as compared to the cast‐in‐place specimen, while their average cracking load, yield load, and ultimate load were 27.9%, 11.0%, and 7.4%, respectively, which is less than those of the cast‐in‐place specimen. Also, the flexural cracking resistance was the highest in the sleeve segment, followed by the joint region and the rebar segment. This study provides a reference for the design of the UHPC grouted sleeve connection for assembled precast elements. [ABSTRACT FROM AUTHOR]

Published

2023

11. Performance-based assessment of slender reinforced concrete columns typical of precast industrial buildings.

Author

Deyanova, M., Bellotti, D., Nascimbene, R., and Pampanin, S.

Subjects

*CONCRETE columns, *REINFORCED concrete, *AUTHENTIC assessment, *EARTHQUAKE damage, *COLUMNS, *INDUSTRIAL buildings

Abstract

Typically, the columns of the prefabricated reinforced concrete (RC) industrial buildings and warehouses with large clear storey heights are very slender, with aspect ratios (shear span to width) larger than 10. In addition to supporting the gravity loads, the columns also provide strength, stiffness, dissipation and displacement capacity of the primary lateral-load resisting system. However, current empirical relationships that predict the non-linear response and failure mechanisms of RC columns have been developed mainly for lower aspect ratios (< 7), typical of ordinary multi-storey buildings or short-to-medium bridge piers. What makes slender columns different is their predominant flexural response, larger drifts at nominal strength and corresponding lower ductility demands, smaller ratios between the strain penetration and plastic hinge lengths to the element shear span and risk of P-Delta instability. Therefore, the direct application of analytical models available in the literature to slender columns poses a risk of overestimation of their deformation and dissipative capacity. In turns this could lead to the underestimation of their displacement demand, overall damage and collapse probability of the primary seismic-resisting and load-bearing system. In the present research extensive analysis on the non-linear response of slender columns was performed based on observed post-earthquake damage to buildings in Italy and Turkey, experimental data and numerical predictions of the failure patterns through non-linear fiber element models. The influence of the foundation flexibility and the presence of industrial floor was also investigated. The outcome is a simplified analytical methodology for the prediction of the non-linear force–deformation response and possible failure mechanisms of slender precast columns due to rebar buckling or P-Delta effects, as a fundamental step towards the seismic assessment of the global structural performance and cost-efficient retrofit solutions for precast concrete industrial buildings. [ABSTRACT FROM AUTHOR]

Published

2023

12. Finite element modelling of a beam to column dowel connection calibrated on experimental data.

Author

Moldovan, Marius G. L. and Nedelcu, Mihai

Subjects

FINITE element method, COLUMNS, SPACE frame structures, WOODEN beams, LATERAL loads

Abstract

Copyright of Acta Technica Napocensis: Civil Engineering & Architecture is the property of Universitatea Tehnica din Cluj-Napoca, Facultatea de Constructii and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

13. Slender precast voided slabs under walking‐induced vibration.

Author

Dal Lago, Bruno, Martinelli, Luca, and Foti, Francesco

Subjects

*PRESTRESSED concrete, *CONSTRUCTION slabs, *MODAL analysis, *NUMERICAL analysis, *OFFICE buildings

Abstract

Disturbance/discomfort caused by vibrations, induced by pedestrian walking on slabs in residential/office buildings, is a typical design issue for lightweight slender slabs, including prestressed concrete ones. Precast slabs are typically made with pretensioned members which allow for only partial collaboration in the transverse slab direction, which becomes even less effective when they are dry‐assembled without cast‐in‐situ topping since it relies on the arrangement of mutual mechanical connections only. This study investigates through tests and numerical analyses the response of slender precast long‐span slabs made with voided members, dry‐assembled with mechanical connections, when subjected to vibrations generated by human activities. A parametric set of dynamic modal and time‐history analyses encompassing floor member geometry, connection arrangement, mass, and damping, is carried out. The numerical models are validated against results from an experimental test program carried out on two decks of a prototype precast building. The tests and the numerical models allowed to characterize the fundamental dynamic properties of the slab and its vibrational performance, identifying the most efficient technological solutions among those investigated to mitigate human‐induced vibrations [ABSTRACT FROM AUTHOR]

Published

2022

14. Development of a Dataset from Shaking Table Tests of a Bridge System with Precast Reinforced Concrete Columns Equipped with Springs.

Author

Reggiani Manzo, Natalia, Vassiliou, Michalis F., Mouzakis, Harris, Badogiannis, Efstratios, and Karapitta, Lucia

Subjects

*SHAKING table tests, *CONCRETE columns, *PRECAST concrete, *REINFORCED concrete, *BRIDGE testing, *BRIDGE failures, *BRIDGE foundations & piers, *EARTHQUAKE resistant design

Abstract

This article describes the publicly available dataset of multiple shaking table tests on a restrained rocking and sliding bridge system exhibiting negative lateral stiffness. Given the scarcity of experimental campaigns on such systems, this dataset is valuable for the development and validation of analytical and numerical models, with 184 tests. This large body of data allows the models to be validated in a statistical sense. This work describes in detail the specimen and its construction, as well as all instrumentation used during the tests. It presents the organization of the shared data, and concludes with some examples of how the available data can be postprocessed for assessing the behavior of the system. [ABSTRACT FROM AUTHOR]

Published

2022

15. An Innovative and Sustainable Wet Joint Between Precast Beam and Columns from the Oil & Gas

Author

Colone, V., Lopriore, P., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, and Menegotto, Marco, editor

Published

2020

16. Criteria for the Structural Analysis of Precast Buildings with Dissipative Connection Systems of Cladding Wall Panels

Author

Toniolo, G., Biondini, F., Dal Lago, B., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, and Menegotto, Marco, editor

Published

2020

17. Seismic Behavior of Precast Buildings With Dissipative Connections

Author

Lorenzo De Stefani and Roberto Scotta

Subjects

seismic design, precast structures, dissipative connections, elasto-plastic connection, precast and cantilever erection, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9

Abstract

Recent earthquakes in southern Europe highlighted that the connections of cladding panels to R.C. frames in precast buildings had a major role in the structural collapse. For this reason, there is an urgent need for a review of the design methods for these connections as well as for an improvement in the manufacturing technology. This article aimed to assess the efficiency of dissipative panel-to-structure and roof connections in R.C. precast buildings. A parametric study consisting of linear and non-linear analyses on one case-study building is performed. Different sensitivity analyses are performed varying their mechanical properties (i.e., stiffness, strength, and ductility) to analyze the behavior of the CP/frame connections. The study focuses on dissipative connections with an elastic–plastic behavior, placed between cladding panels (CPs) and frames in precast buildings with stacked horizontal cladding panels. The introduction of dissipative CP/frame connections implies the inclusion of panels in the global seismic resisting system. The “panels + frame” system highlights a high stiffness until the yield strength of the CP/frame connections is reached. The results, obtained from non-linear dynamic analyses (NLDAs), clearly show how the proposed connection improves the structural seismic performance. By contrast, this is no longer true for R.C. precast structures with flexible diaphragms, especially for intermediate columns, far from panels aligned to seismic action. In this case, significant and unexpected axial forces arise on out-of-plane connections between panels and columns. The integration of an efficient diaphragm is essential to prevent these critical issues both on intermediate columns and CP/column connections; it enables the dissipative capacity of the “panels + frame” system, and it significantly limits the forces and displacements of intermediate alignments. Unfortunately, the achievement of a rigid diaphragm is not always feasible in precast buildings. A possible alternative to activate dissipative capacities of the roof diaphragm with limited in-plane stiffness is the use of dissipative connections linking roof beams and main beams. The solutions described in this article can be applied both in the design of new buildings and for the seismic upgrading of existing ones with easy-to-install and low-impact applications.

Published

2021

18. Early Developments of Concrete Prefabrication

Author

Fernández-Ordóñez Hernández, David, Hordijk, D.A., editor, and Luković, M., editor

Published

2018

19. Displacement-based design of precast hinged portal frames with additional dissipating devices at beam-to-column joints.

Author

Belleri, Andrea and Labò, Simone

Subjects

*CONCRETE joints, *ENERGY dissipation

Abstract

The seismic performance of precast portal frames typical of the industrial and commercial sector could be generally improved by providing additional mechanical devices at the beam-to-column joint. Such devices could provide an additional degree of fixity and energy dissipation in a joint generally characterized by a dry hinged connection, adopted to speed-up the construction phase. Another advantage of placing additional devices at the beam-to-column joint is the possibility to act as a fuse, concentrating the seismic damage on few sacrificial and replaceable elements. A procedure to design precast portal frames adopting additional devices is provided herein. The procedure moves from the Displacement-Based Design methodology proposed by M.J.N. Priestley, and it is applicable for both the design of new structures and the retrofit of existing ones. After the derivation of the required analytical formulations, the procedure is applied to select the additional devices for a new and an existing structural system. The validation through non-linear time history analyses allows to highlight the advantages and drawbacks of the considered devices and to prove the effectiveness of the proposed design procedure. [ABSTRACT FROM AUTHOR]

Published

2021

20. Tension-only ideal dissipative bracing for the seismic retrofit of precast industrial buildings.

Author

Dal Lago, Bruno, Naveed, Muhammad, and Lamperti Tornaghi, Marco

Subjects

*INDUSTRIAL buildings, *RETROFITTING, *SEISMIC response, *STRUCTURAL frames, *EARTHQUAKE resistant design

Abstract

New precast frame industrial structures are seismically designed according to reliable modern criteria. However, most of the existing built stock hosting many workers and both regular and strategic industrial activities was designed and detailed neglecting the earthquake load or according to outdated seismic design criteria and regulations. Its seismic retrofit is a main challenge for the Engineering Community and a critical objective for institutional and private bodies. Among the envisaged solutions, the introduction of dissipative braces appears to be promising, although mostly inapplicable for these buildings, due to the brace lengths required by their typical large dimensions and the related proportioning against buckling. In this paper, an innovative seismic retrofitting technique based on monolateral dissipative bracing is investigated. The device proposed in this paper, yet in phase of preliminary design and testing, dissipates energy through friction in tension only while freely deforming in compression, which makes the issue related to compressive buckling irrelevant. A numerical analysis is carried out to investigate the efficiency of the proposed device in seismic retrofitting of precast industrial frame buildings with the aim to explore its feasibility and to better orient the definition of the slip threshold load range and the future development of the physical device. The simplified Capacity Spectrum Method (CSM) is employed for the global framing of the structural behaviour of the highly nonlinear retrofitted structures under seismic actions. A numerical tool is set to automatically apply the CSM based on the definition of few main parameters governing the seismic response of precast frame structures. The efficacy of the CSM is critically analysed through the comparison with the results of a set of nonlinear dynamic analyses. A smart simplified design process aimed at framing the most efficient threshold slip/yield load of the device given an existing structural configuration is presented with the application of the CSM through the identification of the most efficient performance indicator related to either displacement, shear force, equivalent dissipation of energy or a combination of them. [ABSTRACT FROM AUTHOR]

Published

2021

21. Keyed shear connections with looped U‐bars subjected to normal and shear forces Part I: Experimental investigation.

Author

Sørensen, Jesper Harrild, Hoang, Linh Cao, and Poulsen, Peter Noe

Subjects

*SHEARING force, *DIGITAL image correlation, *SHEAR (Mechanics), *COMPRESSIVE force, *SHEAR strength

Abstract

Shear connections in prefabricated concrete buildings are important for the structural performance in both the serviceability and the ultimate limit state. A normal force has a large impact on the shear strength and deformation capacity, however, no experimental record includes compression–shear and tension–shear interaction. This article presents an experimental investigation of keyed shear connections with looped U‐bars subjected to combinations of shear and normal forces. The tests were performed in a custom‐built double frame, where forces could be applied in two perpendicular directions, which was utilized to introduce normal and shear forces. The load combinations ranged from pure tension, over shear–tension and pure shear to shear–compression. The results include load–displacement relationships supplemented by digital image correlation (DIC) results to exemplify the experimental findings and underline the influence of a normal force on the behavior. It was found that a compressive normal force has a positive influence on the shear capacity in the entire displacement domain tested. A tensile normal force reduces not only the shear capacity but also the deformation capacity of the connection. The ultimate shear load was associated with failure in the joint mortar, which in all cases took place as a local key corner shearing. This article constitutes Part I of the investigation, while Part II introduces rigid‐plastic modeling of the ultimate load carrying capacity. [ABSTRACT FROM AUTHOR]

Published

2021

22. Keyed shear connections with looped U‐bars subjected to normal and shear forces Part II—rigid‐plastic modeling of the ultimate capacity.

Author

Sørensen, Jesper Harrild, Hoang, Linh Cao, and Poulsen, Peter Noe

Subjects

*SHEARING force, *JOINTS (Engineering), *INTERNAL friction, *FAILURE mode & effects analysis, *PRECAST concrete, *MORTAR

Abstract

When the structural capacity of precast concrete structures is to be determined, reliable and practical models for estimation of the ultimate load carrying capacity of the structural connections are essential. In this paper, rigid‐plastic upper bound solutions for the load carrying capacity of keyed shear connections subjected to shear and normal forces are derived and compared to experimental results. The solutions are based on two idealized failure mechanisms involving complete key cut off and local key corner shearing, respectively. The solutions furnish a tool to design connections for the most ductile failure mode, which according to experimental observations is the one with local key corner shearing. Comparison with test results shows that satisfactory overall agreement is found, when appropriate material parameters are adopted. This includes an effectiveness factor, which in this study has been taken from previous studies of similar problems, and an internal angle of friction for mortar in the range of 30°–34°. The agreement is better for combinations of shear and compression, whereas the case of shear combined with large tension forces (i.e., half the yield capacity of the U‐bars) is overestimated by the solutions. Based on the results, it can be recommended that the solutions may be applied in practice using the lower limit for the internal angle of friction, and provided that precaution are taken in cases where the connections are utilized to transfer tension. [ABSTRACT FROM AUTHOR]

Published

2021

23. Multi-Stripe Seismic Assessment of Precast Industrial Buildings With Cladding Panels

Author

Krunal Gajera, Bruno Dal Lago, Luca Capacci, and Fabio Biondini

Subjects

seismic vulnerability, precast structures, industrial buildings, probabilistic assessment, panel connection systems, multi-stripe analysis, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9

Abstract

Following the empirical observation of widespread collapses of cladding panel connections of precast industrial buildings under recent seismic events, new design solutions have been developed in the framework of the European project SAFECLADDING, including isostatic systems effectively decoupling the seismic response of frame structure and cladding panels. The present paper is aimed at evaluating the seismic response and vulnerability of precast frame structures employing pendulum, cantilever, and rocking cladding connection systems. Within the framework of the research project RINTC–Implicit seismic risk of code-conforming structures funded by the Italian Civil Protection Department within the ReLUIS program, the seismic performance of a typical precast industrial building has been assessed with a probabilistic approach based on the results of static and multi-stripe dynamic non-linear analyses. The seismic vulnerability assessment of each structural system has been carried out with reference to life safety and damage limit states considering three sites of increasing seismic hazard in Italy. The effect of distributed panel mass modeling vs. more common lumped mass modeling has been analyzed and critically commented based on the results of demand over capacity (D/C) ratios. Moreover, biaxial seismic D/C ratios have been evaluated for realistic strong hinge connections for cladding panels.

Published

2021

24. Suitability of different tests for characterization of the dimpled concrete‐to‐concrete interface.

Author

Čairović, Đorđe, Fuente, Albert, Zlámal, Martin, Venclovský, Jakub, Girgle, František, Januš, Ondřej, and Štěpánek, Petr

Subjects

*SHEAR strength, *FAILURE mode & effects analysis, *TENSILE strength, *POLYETHYLENE, *PRECAST concrete

Abstract

The main aim of this study was to assess the suitability of different existing test setups for the mechanical characterization of a dimpled interface obtained by casting concrete against dimpled high‐density polyethylene (HDPE) membrane. Even though this type of interface roughening is widely used, especially for monolithic connections between precast elements, to the best of the authors' knowledge there is no research providing any data regarding its roughness parameters, tension, and shear strength, nor its failure modes. To this end, a two‐fold objective was established for this research: (a) to identify and analyze, from a technical standpoint, the available test configurations for characterizing the mechanical performance of interfaces, and (b) to perform an extensive experimental program devoted to characterizing the mechanical performance of a dimpled HDPE membrane—cast concrete interface. The suitability of each test for reproducing the expected stress state and the actual resistance mechanism was analyzed. Moreover, a comparison between tension and shear tests, including its main advantages and disadvantaged are also presented. [ABSTRACT FROM AUTHOR]

Published

2021

25. Cyclic Behavior of Beam-Column Connections in Precast Structures

Author

Hilal Meydanli Atalay and Sevket Ozden

Subjects

precast structures, moment-resisting connection, post-tensioning bolt, spring steel, strength, ductility, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9

Abstract

The performance of precast concrete structures is greatly influenced by the response of beam–to-column connections. In this study, a new moment resisting precast concrete beam-column connection detail with post-tensioning bolts, made out of high yield strength spring steel, has been experimentally investigated as an alternative to the conventional precast moment resisting connections. Precast specimens and an aseismic monolithic reference specimen have been tested under reverse cycling loads. The contribution of the mild steel in the connection region to the flexural moment capacity, and to the initial pre-stressing force on post-tensioning bolt have been the main test variables. The moment capacity, stiffness, energy dissipation capacity and the residual displacement performance of the precast connections have been compared with those of the aseismically detailed monolithic connection. The conducted tests reveal that the connection detail with steel corbel along with the post-tensioning bolt and mild steel has superior performance properties as compared to the companion precast specimens.

Published

2021

26. Modeling of the Beam-To-Column Dowel Connection for a Single-Story RC Precast Building

Author

Gennaro Magliulo, Chiara Di Salvatore, and Marianna Ercolino

Subjects

precast structures, dowel connection, nonlinear model, pushover analysis, multistripe analysis, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9

Abstract

As widely known, connections performance under seismic loads can significantly affect the structural response of RC precast buildings. Within the scientific community, an increasing number of studies has been carried out on this topic, in the light of the recent earthquake aftermaths all over Europe. Indeed, connections turned out to be the weakest part of the precast structures and their failure often provoked the global collapse of the whole building. The present study aims at assessing the seismic behavior of a single-story RC precast building in terms of global collapse implementing two different models of the beam-to-column connection, a simplified and a refined one. A lumped plasticity approach is used to simulate the structural nonlinear behavior at the column base. In order to assess the refined connection model, a preliminary scheme with an isolated single dowel is validated by comparing the pushover outcomes with experimental results from literature. Nonlinear static and dynamic analyses are performed on two models of a 3D single-story RC precast building, one implementing the simple beam-to-column connection model and the other one implementing the refined mode. The comparison clearly shows that the differences are negligible if the global collapse limit state is considered.

Published

2021

27. ROC analysis-based optimal design of a spatio-temporal online seismic monitoring system for precast industrial buildings.

Author

Ierimonti, Laura, Venanzi, Ilaria, and Ubertini, Filippo

Subjects

*INDUSTRIAL buildings, *RECEIVER operating characteristic curves, *INTELLIGENT buildings, *NATURAL disaster warning systems, *ONLINE monitoring systems, *REINFORCED concrete buildings, *PRECAST concrete, *EARTHQUAKE zones

Abstract

The aim of this work is to propose an efficient tool for the design of the monitoring system of precast reinforced concrete industrial buildings in seismic hazard zones, enabling the rapid post-earthquake damage assessment. The methodology, designated as spatio-temporal online monitoring (STOM) is performed by analyzing data obtained from a set of bi-directional accelerometers integrated in smart columns within the building. Acceleration records are converted into inter-story drift ratio (IDR) data, designated as engineering demand parameters, by double integration. Then, calculated IDRs are compared to three levels of alert thresholds meaning that, for the selected damage state, the structure is classified as apparently safe, restricted use or unsafe, corresponding to slight damage, moderate damage and severe damage. Finally, the STOM results trigger visual inspections, thus representing the main inputs needed by engineers in order to evaluate the structural health status and eventually decide for further actions. Measurements data are collected across time as well as space to ensure greater robustness and effectiveness. The STOM methodology allows the preliminary design, i.e., number and location of sensors and optimal demand thresholds, by exploiting the receiver operating characteristics (ROC) analysis, which classifies the different options on the basis of their performance in reporting true damage scenarios with respect to false alarms. Hence, seismic monitoring data are used in conjunction with the pre-evaluated alert states as an engineering decision-support tool for the post-earthquake diagnosis of the structure. [ABSTRACT FROM AUTHOR]

Published

2021

28. Out-of-plane capacity of cladding panel-to-structure connections in one-story R/C precast structures.

Author

Menichini, Giovanni, Del Monte, Emanuele, Orlando, Maurizio, and Vignoli, Andrea

Subjects

*NUCLEAR fuel claddings, *EFFECT of earthquakes on buildings, *SEISMIC response, *MATERIALS testing, *ENVIRONMENTAL engineering, *CIVIL engineering, *NUMERICAL analysis, *LIGHT water reactors, *WALLS

Abstract

The interaction between cladding panels and the main structure is a crucial point to assess the seismic response, and above all the structural safety, of RC precast industrial building. In the past, connections were often designed to allow construction tolerances and to accommodate both thermal and wind-induced displacements. The lack of specific details to allow relative in-plane displacements between cladding panels and the main structure often led to the participation of cladding panels in the structure seismic-resistant system with consequent connection failures. In the last decades, a lot of experimental tests were performed to investigate the in-plane performance of panel connections, and some design recommendations have been developed accordingly. In the out-of-plane direction, the connections were often considered to be infinitely rigid and not to suffer any damage by the seismic load. This work deals with the out-of-plane response of panel-to-structure connections for vertical panels typical of industrial and commercial precast buildings. Both standard hammer-head strap and new devices, called SismoSafe, were investigated. Tests were performed in the Structures and Materials Testing Laboratory of the Department of Civil and Environmental Engineering of Florence, where a specific setup was designed to perform cyclic and monotonic tests on the connection devices. Standard connections showed a rather limited resistance, while the innovative connections exhibited a high out-of-plane resistance. Numerical analyses were also performed on a case study building to evaluate the distribution of the out-of-plane demand on the connections. [ABSTRACT FROM AUTHOR]

Published

2020

29. Displacement-Based Simplified Seismic Loss Assessment of Italian Precast Buildings.

Author

Bosio, Marco, Belleri, Andrea, Riva, Paolo, and Marini, Alessandra

Subjects

*COLUMN design & construction, *EARTHQUAKE hazard analysis, *PRECAST concrete, *GIRDERS, *REINFORCED concrete, *INDUSTRIAL buildings

Abstract

Economic losses associated with the structural and non-structural damage occurring after an earthquake are of particular importance in the case of industrial buildings due to the consequences of such losses on the local economy and employment level. The seismic sequences that hit the industrial area of Emilia-Romagna region of Italy in 2012 represent an emblematic example. In this earthquake event, major damage on poorly performing precast structures was recorded: many buildings were severely damaged and experienced partial or full collapse. The level of the recorded damage was related to a design lacking modern seismic detailing and to a non-up-to-date evaluation of the seismic hazard: in fact, several industrial buildings, typically one storey precast reinforced concrete (RC) structures, were designed to transfer horizontal loads (i.e. between roof elements and supporting beam or main girder and supporting columns) through either friction or under-designed mechanical connections. The aim of this paper is to provide insights on the evaluation of direct losses in the case of precast RC structures typical of the Italian industrial sector, particularly for buildings built before the enforcement of modern seismic codes. A simplified displacement-based seismic loss assessment procedure is proposed and applied to a selected case study and comparisons are made with the results obtained from non-linear time history analyses on simplified (i.e. single column models) and complete three-dimensional models. Retrofit solutions are proposed and their influence on the collapse probability of the structural elements and on the economic losses is evaluated. [ABSTRACT FROM AUTHOR]

Published

2020

30. Flexural behavior of wet panel-to-panel groove-and-tongue joints provided with lapped U-bars.

Author

Dong, Ao, Li, Zhenyu, Rong, Bin, Wang, Changxiang, Wang, Zeming, and Xu, Hui

Subjects

*STRUT & tie models, *PRECAST concrete, *REINFORCING bars, *CONCRETE panels

Abstract

• U-bars with a lap length of 15 times the bar diameter achieves the same load-bearing capacity as straight-through bars. • Groove-and-tongue joints have a positive impact on the bending performance of panels. • Established a Strut-and-Tie model for lapped U-bars. • Analyzed the interaction between U-bars and core concrete, and determined the calculation method for their contact height. A comprehensive experimental campaign was carried out to investigate the flexural behavior of wet joints provided with lapped U-bars connecting two precast concrete panels. Eleven assemblies were tested in 4-point bending. Nine assemblies had wet groove-and-tongue joints provided with U-bars, and different values for the overlap length, joint width, and concrete strength. As a reference, the remaining two assemblies had wet groove-and-tongue or flat joints reinforced with straight-through bars. All the assemblies but two were provided with water-stop strips. The test results show that a lap length of 15 times the bar diameter is sufficient to guarantee the same bending capacity as straight-through bars. Based on the deformations of the panels subjected to bending, a strut-and-tie model was developed to predict the flexural capacity of linear wet joints provided with lapped U-bars. The proposed model effectively predicts the flexural capacity of the assembly of two panels since the theoretical predictions and the test results differ by less than 10%. [ABSTRACT FROM AUTHOR]

Published

2024

31. Betonarme Manto Uygulamasının Prefabrike Yapıların Deprem Performansına Etkisi.

Author

SOYDAN, Cihan and ÖZKAYNAK, Hasan

Abstract

The majority of industrial buildings located in our country consist of single-story precast systems with pinned beam-to-column connections. Observations made after earthquakes showed that due to high lateral displacement demands occurred under the effects of earthquake loads; significant damage was accumulated throughout the beam-to-column connections and whole structure. Strengthening such building systems against earthquake loads is not only crucial for high-cost devices and machinery but also very important in terms of human life as a priority. In this study, the effects of reinforced concrete (RC) jacketing technique on the global earthquake performance of precast structures was examined numerically. In the first part of the study, experimental results of bare and RC jacketed columns, which exist in the recent literature, were used as a benchmark for the development of numerical models. The force-displacement relations obtained from quasi-static experiments were compared with the numerical results. The numerical models are successful to estimate the experimental results within the range of distinct displacement levels. Validated numerical models were used for nonlinear dynamic analysis of an existing 3D precast system. Numerical results showed that the application of RC jacketing technique is effective to decrease the average maximum and minimum drift values by the ratios of 54-72%. Determinations of strain levels for the selected columns of the system showed that; the RC jacketing retrofitting technique is effective to increase the sectional performance by shifting the strain demands from safety limit (GV) to minimum damage limit (MN). [ABSTRACT FROM AUTHOR]

Published

2019

32. Diaphragm effectiveness of precast concrete structures with cladding panels under seismic action.

Author

Dal Lago, Bruno, Bianchi, Silvia, and Biondini, Fabio

Subjects

*PRECAST concrete, *STRUCTURAL mechanics, *SEISMOLOGY, *STRUCTURAL design, *DIAPHRAGMS (Mechanical devices)

Abstract

The seismic performance of precast frame structures strongly depends on the mechanical devices connecting both structural and non-structural elements. Following recent post-earthquake field observations of unintended seismic interaction of the cladding panels with the frame structure, the seismic design of the cladded system is currently being critically examined by the scientific community. Design solutions involving a controlled cladding-structure interaction have been proposed to address this problem. However, the frame-panel interaction may draw high stresses into the roof diaphragm, as a consequence of the stiffening of the external frames only. This paper presents a parametric study based on linear and non-linear dynamic analyses investigating different levels of interaction among frames, panels, and diaphragm system. The results show how the deck and cladding connections influence the seismic behaviour of the structure. Innovative fastening systems aimed at enhancing the seismic performance of the structure are proposed based on the use of dissipative connection devices inserted into both cladding and deck components. [ABSTRACT FROM AUTHOR]

Published

2019

33. Slender precast voided slabs under <scp>walking‐induced</scp> vibration

Author

Bruno Dal Lago, Luca Martinelli, and Francesco Foti

Subjects

discomfort, vibrations, Mechanics of Materials, numerical simulation, smartphone-assisted testing, design against vibrations, prestressed slabs, General Materials Science, Building and Construction, precast structures, Civil and Structural Engineering

Published

2022

34. Implementação da metodologia BIM na pré-fabricação de betão: estudo de caso em empresa brasileira

Author

Benetti, Vinicius Piassa, Silva, Paulo Alexandre da Silveira Costeira Marques da, and Dias, Gustavo Lacerda

Subjects

Industrialização, Implementação do BIM, Precast Concrete, Engenharia e Tecnologia::Engenharia Civil [Domínio/Área Científica], Pré-fabricação de betão, Estruturas Pré-fabricadas, Precast Structures, Industrialization, BIM – Building Information Modelling

Abstract

A pré-fabricação, mesmo possuindo diversos benefícios e motivos favoráveis para a sua utilização, ainda é uma técnica construtiva pouco utilizada e disseminada fora dos territórios mais setentrionais da Terra, em comparação com a construção tradicional. Novas tecnologias introduzidas no setor da construção, como o BIM (Building Information Modelling) podem não ser tão facilmente adaptadas a este estilo construtivo por não serem convencionais. A ascensão do BIM como uma tecnologia avançada com perspetiva de consolidação no setor da construção, necessita de ferramentas que se apliquem e auxiliem a sua inserção no mercado da pré-fabricação. O crescimento e expansão da metodologia BIM aponta uma direção no sentido da industrialização da construção, que pode ser impulsionada pela sua utilização também na área da pré-fabricação através da aplicação de conceitos industriais e de produção repetitiva e contínua. O processo de implementação do BIM envolve uma mudança significativa nos processos de operação de uma empresa. O presente trabalho pretende contribuir para a utilização do BIM no setor da pré-fabricação, mostrando como uma empresa de construção civil, especializada em pré-fabricação de betão, realizou a implementação do BIM nas suas operações, descrevendo o processo de transição, as tecnologias e os softwares adotados, a forma como os intervenientes se capacitaram e identificando o impacto que estas novas tecnologias introduziram na atuação e operação da empresa. Com a informação obtida no estudo de caso apresenta-se uma análise das informações reunidas da empresa que possam ser úteis para que outras empresas do setor da pré-fabricação possam avançar com a utilização do BIM. Assim, é feita a avaliação da situação da empresa neste processo de transição, bem como são identificados os principais benefícios e desafios encontrados no processo. Por fim, apresentam-se algumas recomendações para a implementação do BIM e sintetizam-se as principais conclusões deste estudo. ABSTRACT: Prefabrication, even though it has several benefits and favourable reasons for its use, is still a construction technique less often used and disseminated outside the northernmost territories of the Earth, compared to traditional construction. New technologies introduced into the construction industry, such as BIM (Building Information Modelling) may not be as easily adapted to this construction style due to not being conventional. The rise of BIM as an advanced technology with the prospect of consolidation in the construction sector requires tools that apply and assist its insertion in the prefabrication market. The growth and expansion of BIM methodology points in the direction of the industrialization of construction, which can be boosted by its use also in the prefabrication area through the application of industrial concepts and repetitive and continuous production. The BIM implementation process involves a significant change in the company's operation processes. This research aims to contribute to the use of BIM in the precast concrete sector, showing how a construction company, specialized in concrete precast, carried out the implementation of BIM in its operations, describing the transition process, the technologies and software adopted, how stakeholders were trained and identifying the impact that these new technologies introduced in the company's performance and operation. With the information obtained in the case study, an analysis is presented of the information gathered from the company that can be useful for other companies in the prefabrication sector to move forward with the use of BIM. Thus, the evaluation of the company's situation in this transition process is made, as well as the main benefits and challenges encountered in the process are identified. Finally, some recommendations for BIM implementation are presented and the main conclusions of this study are summarized.

Published

2023

35. Seismic Risk and Finite Element Modelling Influence of an Existing One-Storey Precast Industrial Building

Author

Marco Bosio, Simone Labò, Paolo Riva, and Andrea Belleri

Subjects

seismic risk, friction connections, Precast structures, industrial buildings, beam- column connections, Building and Construction, Geotechnical Engineering and Engineering Geology, Settore ICAR/09 - Tecnica delle Costruzioni, Civil and Structural Engineering

Published

2023

36. Influence and effectiveness of horizontal diaphragms and cladding wall panels on the seismic behaviour of precast RC industrial buildings

Author

Liana Ostetto, Romain Sousa, Paulo Fernandes, and Hugo Rodrigues

Subjects

Cladding panels, Seismic behaviour, Precast structures, Roof diaphragm, Non-structural elements, Industrial buildings, Civil and Structural Engineering

Abstract

The seismic behaviour of precast reinforced concrete industrial structures has been extensively investigated in recent decades, especially after the damage caused by recent earthquakes. The interaction of the roof’s horizontal diaphragm with the structural and non-structural elements can influence the seismic behaviour of these buildings. Thus, the present study aims to investigate this interaction, through nonlinear static and dynamic analyses using a simplified macro element to simulate the behaviour of cladding panels and an equivalent truss approach to simulate the roof in-plane stiffness. The analyses were performed on several structural models considering the current European single-storey precast reinforce concrete industrial building stock, with or without cladding wall panels, and with rigid or flexible diaphragm roof. Despite the uncertainties associated with the ability of common roof systems to ensure a rigid diaphragm, the analyses allowed the establishment of a correlation between the buildings generic properties and the roof horizontal stiffness required to approach a rigid diaphragm effect. In general, the results show that the consideration of a rigid diaphragm in numerical models may tend to produce a more realistic seismic behaviour of the overall structure. Furthermore, the contribution of facade cladding wall panels significantly influences the seismic behaviour of the building, especially for high-rise buildings. published

Published

2023

37. Influence of Cladding Panels Retrofit on the Seismic Risk of an Existing Precast Building

Author

ETEME MINKADA, Marius, Bosio, Marco, Belleri, Andrea, and Riva, Paolo

Subjects

Precast Structures, Seismic Risk, Settore ICAR/09 - Tecnica delle Costruzioni, Industrial Buildings

Published

2023

38. Development of a Dataset from Shaking Table Tests of a Bridge System with Precast Reinforced Concrete Columns Equipped with Springs

Author

Natalia Reggiani Manzo, Michalis F. Vassiliou, Harris Mouzakis, Efstratios Badogiannis, and Lucia Karapitta

Subjects

Mechanics of Materials, Mechanical Engineering, General Materials Science, Building and Construction, Earthquake engineering, Concrete structures, Precast structures, Bridge engineering, Seismic isolation, Recentering systems, Resilient systems, Rocking systems, Negative stiffness, Civil and Structural Engineering

Abstract

This article describes the publicly available dataset of multiple shaking table tests on a restrained rocking and sliding bridge system exhibiting negative lateral stiffness. Given the scarcity of experimental campaigns on such systems, this dataset is valuable for the development and validation of analytical and numerical models, with 184 tests. This large body of data allows the models to be validated in a statistical sense. This work describes in detail the specimen and its construction, as well as all instrumentation used during the tests. It presents the organization of the shared data, and concludes with some examples of how the available data can be postprocessed for assessing the behavior of the system. © 2022 American Society ofCivil Engineers. ISSN:0733-9445 ISSN:1943-541X

Published

2022

39. Análise dinâmica de vigas longas de concreto protendido pré-moldadas durante operações de içamento

Author

Lima, Gabriel Henrique Arruda Tavares de, Krahl, Pablo Augusto, Lima, Maria Cristina Vidigal de, Gonçalves, Lauren Karoline de Sousa, and Siqueira, Tiago Morkis

Subjects

dynamical behavior, estrutura pré-moldada, ENGENHARIAS::ENGENHARIA CIVIL::ESTRUTURAS::ESTRUTURAS DE CONCRETO [CNPQ], fator de impacto, lateral stability, Vigas de concreto protendido, estabilidade lateral, fases transitórias, comportamento dinâmico, Concreto pré-moldado, precast structures, impact factor, Engenharia Civil, transitory phases

Abstract

Pesquisa sem auxílio de agências de fomento A tendência da utilização de seções transversais esbeltas devido à utilização de materiais de alto desempenho, tornam as vigas mais propensas ao fenômeno de instabilidade lateral durante as fases transitórias, especialmente no içamento. As vigas de concreto pré-moldado são levantadas durante a construção por guindastes. Vários movimentos devem ser realizados para montar a estrutura. No entanto, não há recomendação para velocidades de operação específicas para vigas longas, mas vários colapsos foram relatados nessa etapa de construção. Na literatura técnica até então este problema só foi abordado por meio de análise estática. Portanto, a presente pesquisa tem como objetivo investigar o comportamento dinâmico de vigas protendidas longas, identificando velocidades operacionais críticas de acordo com a movimentação dos guindastes. A excentricidade dos cabos de protensão e desvios de posicionamento das alças de içamento foram consideradas na análise, por acentuarem os riscos de instabilidade. Na pesquisa, foram realizadas análise modal e análise dinâmica transiente considerando a não linearidade geométrica, para uma viga de concreto pré-moldado protendido com 40 m de vão. A análise foi realizada com um modelo 3D de elementos finitos, e o sistema com múltiplos graus de liberdade foi testado em movimentos ascendente, descendente e lateral. O movimento mais crítico observado foi o movimento lateral, pois mobiliza mais a rigidez lateral das vigas esbeltas excitando as frequências de oscilação próximas à frequência natural da viga. A segurança contra a fissuração e subsequente falha durante os movimentos verticais e laterais foi verificada para velocidades de operação do guindaste de 36 cm/s e 17 cm/s, respectivamente. Para o caso mais crítico analisado, evidenciou-se na análise dinâmica um aumento de 12 vezes nas tensões de tração comparada à situação de equilíbrio estático da viga, 80% nas tensões de compressão e uma amplificação de 5 vezes na rotação da viga. The tendency to use slender cross-sections due to the use of high-performance materials makes beams more prone to the phenomenon of lateral instability during transient phases, especially during lifting. Precast concrete beams are lifted during construction by cranes. Several movements must be performed to assemble the structure. However, there is no recommendation for specific operating speeds for long beams, but several collapses have been reported at this stage of construction. In the technical literature so far this problem has only been addressed through static analysis. Therefore, the present research aims to investigate the dynamic behavior of long prestressed beams, identifying critical operating speeds according to crane movements. The eccentricity of the prestressing cables and positioning deviations of the lifting loops were considered in the analysis, as they accentuate the risks of instability. In the research, modal analysis and transient dynamic analysis were performed considering the geometric non-linearity, for a prestressed concrete beam with a span of 40 m. The analysis was performed with a 3D finite element model, and the system with multiple degrees of freedom was tested in upward, downward and lateral movement. The most critical movement observed was the lateral movement, as it mobilizes more the lateral stiffness of the slender beams, exciting oscillation frequencies close to the natural frequency of the beam. Safety against cracking and subsequent failure during vertical and lateral movements was verified for crane operating speeds of 36 cm/s and 17 cm/s, respectively. For the most critical case analyzed, the dynamic analysis showed 12 times increase in tensile stresses compared to the static equilibrium situation of the beam, 80% in compressive stresses and a 5 times amplification in beam rotation. Dissertação (Mestrado)

Published

2022

40. Σεισμική Μόνωση Προκατασκευασμένων Λικνιζόμενων Γεφυρών με Τένοντες και Ελατήρια: Δοκιμές Σεισμικής Τράπεζας

Author

Reggiani Manzo, Natalia, Vassiliou, Michalis F., Mouzakis, Harris, Badogiannis, Efstratios, and Karapitta, Lucia

Subjects

Bridge design, Precast Structures, Seismic isolation, Earthquake Engineering, Civil engineering, FOS: Civil engineering, ddc:624

Abstract

Παρουσιάζονται οι πειραματικές δοκιμές σε σεισμική τράπεζα ενός λικνιζόμενου συστήματος αρνητικής δυσκαμψίας. Το σύστημα αποτελείται από 4 λικνιζόμενα προκατασκευασμένα υποστυλώματα που στηρίζουν μια πλάκα. Ελεύθεροι τένοντες σε σειρά με κωνικά ελατήρια συνδέουν τα μέλη. Μεταλλικοί μανδύες συνδέουν και προστατεύουν τα άκρα των υποστυλωμάτων. Το δοκίμιο αποτελεί παράδειγμα σχεδιασμού προκατασκευασμένης λικνιζόμενης γέφυρας. Το ανασήκωμα των υποστυλωμάτων δρα ως σεισμική μόνωση και περιορίζει τη ροπή σχεδιασμού του θεμελίου. Το σύστημα υπεβλήθη σε 181 διεγέρσεις. Η μόνη βλάβη που προξένησαν οι 180 διεγέρσεις ήταν μια μικρή απόξεση των χαλύβδινων μανδυών. Το σύστημα κατέρρευσε κατά την τελευταία διέγερση, λόγω της απροσδόκητης αστοχίας του τένοντα σε φορτίο που αντιστοιχεί στη μισή αντοχή σχεδιασμού.

Published

2022

41. Seismic performance of precast concrete structures with energy dissipating cladding panel connection systems.

Author

Dal Lago, Bruno, Biondini, Fabio, and Toniolo, Giandomenico

Subjects

*PRECAST concrete construction, *SEISMIC prospecting, *HEAT sinks (Electronics), *EARTHQUAKE resistant design, *CONCRETE construction

Abstract

The cladding‐structure interaction of precast concrete frame systems under seismic action has not been properly addressed in the past, as shown by several failures occurred under recent earthquakes in Southern Europe, which point out the need of a revision of the current design practice and technology. Dissipative systems of connections are proposed to this purpose within a general framework for seismic design of precast structures with cladding panels. The proposed connection systems consist of friction‐based or plasticity‐based devices interposed in between adjacent cladding panels or between the panels and the resisting frame to control the level of transferred forces and limit the displacements of the structure. Monotonic and cyclic experimental tests are carried out on both single connection devices and structural sub‐assemblies of two panels. Furthermore, cyclic and pseudo‐dynamic tests on a full‐scale prototype of precast structure with cladding panels are performed. The influence on the structural response of silicone sealant is also investigated through experimental testing. The effectiveness of the tested dissipative connections of the cladding panels in enhancing the seismic performance of precast structures is demonstrated by means of nonlinear dynamic analyses considering the influence of the roof diaphragm action. Design guidelines are finally provided for both single connectors and panel structural assemblies based on equilibrium and capacity design criteria. [ABSTRACT FROM AUTHOR]

Published

2018

42. Experimental study on seismic performance of partially precast steel reinforced concrete columns.

Author

Yang, Yong, Xue, Yicong, Yu, Yunlong, and Gao, Fengqi

Subjects

*CONCRETE columns, *SEISMIC response, *CYCLIC loads, *STIFFNESS (Engineering), *DUCTILITY

Abstract

Highlights • Two partially precast SRC columns with precast RPC outer-part are presented. • Effects of section shape, stirrup spacing and axial compression were examined. • A model for calculating the seismic bending moment capacity was proposed. Abstract This paper aims to develop two kinds of innovative precast steel reinforced concrete columns, which are partially precast steel reinforced concrete (PPSRC) columns and hollow precast steel reinforced concrete (HPSRC) columns. Both the two kinds of composite columns have precast reactive powder concrete (RPC) shells, and the PPSRC column has a cast-in-place column core. In this paper, a series of cyclic loading tests on 10 column specimens subjected to combined static axial loading and cyclic lateral loading were carried out to explore their seismic performances. All specimens were evaluated by the failure modes, hysteresis characteristics, strength and stiffness degradation, energy dissipation capacity and ductility. The effects of section shape, stirrup spacing, axial compression and concrete strength of cast-in-place inner-part were investigated in details. The experiment results indicated that the PPSRC columns exhibited more satisfactory seismic behavior than the HPSRC columns in terms of hysteretic behavior, strength degradation, ductility and energy dissipation, while their bearing capacities were almost identical under low axial compression. Steel fibers could effectively prevent the cracked concrete from spalling, therefore, the encased steel shape was efficiently confined by the surrounding concrete during the entire test process. Higher stirrup ratio and lower axial compression of the column leaded to more satisfactory energy dissipation capacity, stiffness degradation and higher ductility. Based on the plastic stress theory, the seismic bending moment capacity analysis was conducted, and the results obtained form the formulas agreed well with those from the experiments. [ABSTRACT FROM AUTHOR]

Published

2018

43. Experimental Investigation on Steel W-Shaped Folded Plate Dissipative Connectors for Horizontal Precast Concrete Cladding Panels.

Author

Dal Lago, Bruno, Biondini, Fabio, and Toniolo, Giandomenico

Subjects

*FOLDED plate structures, *PRECAST concrete, *METAL cladding, *EARTHQUAKE resistant design, *RETROFITTING

Abstract

A dissipative connector device, consisting of a steel plate folded at right angle along three lines to get a W-shaped profile, is proposed for the safe fastening of the horizontal cladding panels of new or existing precast structures under seismic action. Experimental tests are carried out to characterize the hysteretic behavior of the connector device. Different technological features, restraint conditions, and loading protocols are considered. Nonlinear hysteretic models are validated against the results of pseudo-dynamic tests on a full-scale prototype of precast building with cladding panels. Guidelines for the design of the dissipative connector device are provided. [ABSTRACT FROM AUTHOR]

Published

2018

44. Assessment of a capacity spectrum seismic design approach against cyclic and seismic experiments on full‐scale precast RC structures.

Author

Dal Lago, Bruno and Molina, Francisco J.

Subjects

EARTHQUAKE engineering, PRECAST concrete, ENGINEERING, CONCRETE, FINITE element method

Abstract

Summary: Within the last decades, simplified methods alternative to dynamic nonlinear analysis have been developed to estimate the seismic performance of structures toward a performance‐oriented design. Considering drift as the main parameter correlated with structural damage, its estimation is of main importance to assess the structural performance. While traditional force‐based design deals with calibrated force reduction factors based on the expected structural ductility, other methods are based on the definition of a viscous damping factor defined as a function of the expected energy dissipated by the structure. An example is the capacity spectrum method. This method can be applied even without any a priori calibration or designer arbitrariness. This allows considering several peculiarities of the seismic behavior of precast structures, which may be influenced by nontraditional hysteresis of connections and members, interaction with the cladding panels, P‐δ effects, etc. The paper aims at verifying the soundness and accuracy of this method through the comparison of its predictions against the results of cyclic and pseudodynamic tests on precast structures, including single‐ and multistory buildings either stiff or flexible, obtained on full‐scale building prototypes tested within the framework of recent research projects (namely, “Precast Structures EC8,” “Safecast,” and “Safecladding”). Two simple methodologies of determination of the equivalent viscous damping from a force‐displacement cycle, based on the dissipated energy in relation to 2 different estimates of the elastic strain energy, are addressed and compared. Comments on the possible use of this procedure for the estimation of the seismic performance of precast structures are provided. [ABSTRACT FROM AUTHOR]

Published

2018

45. Vulnerability analysis of industrial RC precast buildings designed according to modern seismic codes.

Author

Ercolino, Marianna, Bellotti, Davide, Magliulo, Gennaro, and Nascimbene, Roberto

Subjects

*PRECAST concrete, *INDUSTRIAL buildings, *EARTHQUAKE resistant design, *PROBABILITY theory, *BUILDING failures

Abstract

Seismic performance-based design approach is currently implemented in modern building codes. Design requirements and provisions ensure an adequate structural performance under different intensity levels of seismic action. However, the probability of attainment of a performance level is implicitly considered in the code design approach (provisions and requirements); for instance, the minimum requirements in concrete structures cannot be simply correlated to the probability of collapse of the building as well as to its overall structural response. The aim of this work is to assess the vulnerability with respect to the collapse limit state of industrial single-story RC precast buildings designed according to the current Italian seismic code. The comparison between the Italian code and the Eurocodes is provided throughout the paper. A parametric study is performed by investigating the safety against the collapse of 40 RC single-story precast structures. Multi-stripe analyses are performed by non-linear dynamic analyses at 10 intensity levels. The fragility of the structures is defined by means of the incremental N2 method, which has been demonstrated to be a suitable method for evaluating the collapse capacity of single-story precast buildings. The results demonstrate that the buildings are safe against the collapse mainly because of the structural overstrength with respect to seismic actions. The modelling assumptions are also validated in order to demonstrate the negligible influence of the cracking on the collapse as well as the importance of the geometrical nonlinearities for precast buildings. [ABSTRACT FROM AUTHOR]

Published

2018

46. Seismic design and performance of dry-assembled precast structures with adaptable joints.

Author

Dal Lago, Bruno, Negro, Paolo, and Dal Lago, Alberto

Subjects

*EARTHQUAKE resistant design, *EARTHQUAKE damage, *PRECAST concrete, *CANTILEVERS, *REINFORCED concrete construction

Abstract

Previous research projects and post-earthquake field observation showed that dry-assembled precast frame structures with hinged beams and cantilever columns restrained at their base, if correctly designed and detailed, can attain good seismic performance, mainly due to their flexibility and robustness. Their seismic design is often conditioned by the need of reducing their flexibility by increasing the cross-section of the columns, which, due to minimum reinforcement requirements, results in their over-strengthening. High flexibility may also induce displacement compatibility issues with non-structural elements. The paper concerns the proposal of an innovative enhanced structural frame system, based on the adaptation of hinged beam-column joints into rigid through the activation of special mechanical connection devices performed after the installation of the slab. While keeping all the benefits of the dry prefabrication, the resulting moment-resisting frame is provided with enhanced redundancy and stiffness. A design comparison among three precast frames with similar geometries and different static schemes shows how the joint adaptation can be exploited to optimise the structure by modifying the distribution of bending moment. The results of dynamic non-linear analyses on a three-storey precast structure with adaptable joints tested as a part of the SAFECAST research programme show the seismic performance of this system through different static schemes, and the comparison with the experimental results provides information about the validity of the models and the effectiveness of the technological solutions employed. [ABSTRACT FROM AUTHOR]

Published

2018

47. Modeling and Seismic Response Analysis of RC Precast Italian Code-Conforming Buildings.

Author

Magliulo, Gennaro, Bellotti, Davide, Cimmino, Maddalena, and Nascimbene, Roberto

Subjects

*SEISMIC response, *EARTHQUAKE engineering, *EARTHQUAKE hazard analysis, *EARTHQUAKE resistant design, *EFFECT of earthquakes on buildings

Abstract

In this study, industrial single-story RC precast buildings are investigated. Twenty-four case studies have been considered, in which the column height, the beam spans and the seismic hazard level are varied. The seismic design of the selected case studies is performed according to the Italian building code and additional technical documentation. Three-dimensional nonlinear models are defined to perform static and dynamic analyses for the seismic assessment of the selected case studies. Demand/capacity ratios in terms of the selected engineering demand parameters are computed for ten increasing values of the seismic input return period. [ABSTRACT FROM AUTHOR]

Published

2018

48. Tension-only ideal dissipative bracing for the seismic retrofit of precast industrial buildings

Author

Marco Lamperti Tornaghi, Bruno Dal Lago, and Muhammad Naveed

Subjects

Computer science, 0211 other engineering and technologies, 020101 civil engineering, 02 engineering and technology, Industrial buildings, 0201 civil engineering, Seismic analysis, Dissipative devices, Bracing system, Framing (construction), Precast concrete, Capacity spectrum, Precast structures, Seismic retrofit, Civil and Structural Engineering, 021110 strategic, defence & security studies, business.industry, Building and Construction, Structural engineering, Geotechnical Engineering and Engineering Geology, Brace, Bracing, Geophysics, Buckling, Design process, business

Abstract

New precast frame industrial structures are seismically designed according to reliable modern criteria. However, most of the existing built stock hosting many workers and both regular and strategic industrial activities was designed and detailed neglecting the earthquake load or according to outdated seismic design criteria and regulations. Its seismic retrofit is a main challenge for the Engineering Community and a critical objective for institutional and private bodies. Among the envisaged solutions, the introduction of dissipative braces appears to be promising, although mostly inapplicable for these buildings, due to the brace lengths required by their typical large dimensions and the related proportioning against buckling. In this paper, an innovative seismic retrofitting technique based on monolateral dissipative bracing is investigated. The device proposed in this paper, yet in phase of preliminary design and testing, dissipates energy through friction in tension only while freely deforming in compression, which makes the issue related to compressive buckling irrelevant. A numerical analysis is carried out to investigate the efficiency of the proposed device in seismic retrofitting of precast industrial frame buildings with the aim to explore its feasibility and to better orient the definition of the slip threshold load range and the future development of the physical device. The simplified Capacity Spectrum Method (CSM) is employed for the global framing of the structural behaviour of the highly nonlinear retrofitted structures under seismic actions. A numerical tool is set to automatically apply the CSM based on the definition of few main parameters governing the seismic response of precast frame structures. The efficacy of the CSM is critically analysed through the comparison with the results of a set of nonlinear dynamic analyses. A smart simplified design process aimed at framing the most efficient threshold slip/yield load of the device given an existing structural configuration is presented with the application of the CSM through the identification of the most efficient performance indicator related to either displacement, shear force, equivalent dissipation of energy or a combination of them.

Published

2021

49. Experimental Investigation of Seismic Performance of Precast Concrete Wall–Beam–Slab Joints with Overlapping U-Bar Loop Connections

Author

Feng Chen, Zhiwu Yu, Yalin Yu, Zhipeng Zhai, Qun Liu, and Xiao Li

Subjects

precast structures, overlapping U-bar loop connections, wall–beam–slab joints, seismic performance, quasistatic test, General Materials Science

Abstract

In the era of energy conservation and environmental protection, as well as the industrialization of buildings, precast concrete (PC) structures have been developed and increasingly applied in construction industries due to their advantages of outstanding workability and ecofriendliness. In order to verify the reliability of overlapping U-bar loop connections and a modified form of these connections, and study the seismic performance of PC wall–beam–slab joints with these connection methods, three full-scale wall–beam–slab joints were designed and tested under low reversed cyclic loading, including one cast-in-place (CIP) specimen and two PC specimens. Based on the test results, the seismic performance of the PC joints was studied by comparing their damage process, hysteretic loops and skeleton curves, load-carrying capacity, ductility, equivalent stiffness, and energy dissipation with those of the CIP joint. After analyzing the experimental results, the following conclusions can be drawn: the overlapping U-bar loop connection and its modified form are effective and reasonable; the specimen with the modified connection form showed slightly better mechanical properties; the failure mode of the PC joints was consistent with that of the CIP joint; and the generation, distribution, and development of cracks in the PC specimens were similar to those in the CIP specimen. In addition, the stiffness of the PC joints was similar to that of the CIP joint, and the load-carrying capacity, ductility, and energy dissipation of the PC joints were better than those of the CIP joint. Moreover, the research in this paper can also provide some guidance for assembling wall–beam–slab joints in PC shear wall structures.

Published

2023

50. Conceptual design and full-scale experimentation of cladding panel connection systems of precast buildings.

Author

Toniolo, Giandomenico and Dal Lago, Bruno

Subjects

CONCEPTUAL design, PRECAST concrete, EARTHQUAKE engineering, ENERGY dissipation, EARTHQUAKE resistant design

Abstract

Despite the long series of European research projects that has led to the setting of fully reliable seismic design criteria for precast structures, recent earthquakes have shown that a weak point still exists in the proportioning of the connection systems of cladding wall panels. Following this finding, this paper outlines an organic setting of the design problem of precast concrete structures including cladding-structure interaction and describes three possible solutions, namely, the isostatic, integrated, and dissipative systems. The related fastening arrangements, with the use of existing and innovative connection devices, are also described. This paper comments on the results of the pseudo-dynamic and cyclic tests performed at ELSA Laboratory of the European Joint Research Centre of Ispra (Italy) on a full-scale prototype of precast structure. The conception and the experimental performance of the structure with nine different configurations of either vertical or horizontal wall panel claddings are presented. The analysis of the results highlights the effectiveness of the different solutions in a comparative way. Copyright © 2017 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2017